- Docente: Domenico Casadei
- Credits: 9
- SSD: ING-IND/32
- Language: Italian
- Moduli: Domenico Casadei (Modulo 1) Yasser Gritli (Modulo 2)
- Teaching Mode: Traditional lectures (Modulo 1) Traditional lectures (Modulo 2)
- Campus: Bologna
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Corso:
First cycle degree programme (L) in
Automation Engineering (cod. 9217)
Also valid for Second cycle degree programme (LM) in Electrical Energy Engineering (cod. 9066)
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from Oct 22, 2024 to Dec 19, 2024
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from Sep 17, 2024 to Oct 17, 2024
Learning outcomes
At the end of the course, the student gains insights into the performance of the main electric drives through the analysis of the most common electric machines, power converters and industrial applications. In particular, the student can •model DC machines, synchronous machines and induction machines, •simulate the corresponding electric drives in Matlab/Simulink environment, •understand the closed-loop control schemes for the regulation of torque, speed and position of electric actuators and machines used in industrial applications.
Course contents
Introduction and basic principles
Force on current-carrying conductor. Voltage induced in a moving conductor. Magnetic material and circuits. Coupled coils. Coefficient of coupling. Self and mutual inductances. Voltage equations. Stored energy in the magnetic field. Electromechanical energy conversion principles. Torque production principles. Types of electrical machines.
DC motor drivesSeparately excited DC machines. Mathematical model. Steady state characteristics with armature and field control. Control of DC motors in the constant torque control region and in the field-weakening region. Transition from driving to breaking operation. Single-, double-, and four-quadrant operation with DC-DC converters. Constant torque and constant horsepower operation.
Dynamic model of the DC machine. Dynamic behavior of DC motors with constant flux. Block diagram of a DC motor coupled with a mechanical load. Torque production and control. Closed-loop control of torque and speed. Starting and speed reversal transients. Application DC motor drives.
Brushless DC motor drivesMagnetic circuit analysis. Torque and emf equations. Winding inductances and armature reaction. Torque/speed characteristics: performance and efficiency. The three-phase half-wave brushless DC motor. The three-phase full-wave brushless DC motor. Commutation phenomena. Position sensors. Drive characteristics and control principles. Application of brushless DC motor drives.
Synchronous motor drivesMagnetic circuit analysis of synchronous machines. Synchronous reactances (d-, q-axis). Analysis of steady-state operation. Voltage equations and torque equation. Steady-state characteristics. Open-loop behavior with constant voltage and frequency. Introduction to closed-loop control of current controlled PWM inverter drives.
Brushless AC motor drivesDynamic model of permanent magnet synchronous machines with surface mounted magnets. The dq machine and flux equations. Principles of field orientation. Torque production and control. Dynamic model of permanent magnet synchronous machines with interior magnets. The dq machine and flux equations. Torque production and control. Control of the synchronous machine supplied by current controlled PWM inverter. Simulation of electromechanical transients. Maximum torque capability of the machine in the flux weakening region.
Induction motor drivesAnalysis of induction motors based on steady-state machine model. Torque and machine equations. Steady-state characteristics. Starting of induction motors. Constant terminal volts/hertz operation. Torque characteristics. Low-frequency performance with increased volts/hertz. Constant air-gap flux operation. Torque characteristics. Current-source inverter drive with slip frequency control. Current controlled PWM inverter drive with slip frequency control. Constant-horsepower operation.
Dynamic model of induction machines. The dq machine and flux equations. Torque equation. Principles of field orientation. Machine equations and torque in the rotor flux oriented reference frame. Decoupling control of flux and torque in the rotor flux oriented reference frame. Flux models. Direct scheme and indirect scheme of induction motor field oriented control. Control of the induction machine supplied by current controlled PWM inverter. Simulation of electromechanical transients. Maximum torque capability of the machine in the flux weakening region. Applications
Readings/Bibliography
I. Boldea, S. A. Nasar : ELECTRIC DRIVES, CRC Press, New York, 1999.
P. Vas: VECTOR CONTROL of AC MACHINES, Oxford University Press, New York, 1990.
T.J.E. Miller: SWITCHED RELUCTANCE MOTORS AND THEIR CONTROL. Clarendon Press, Oxford, 1993.
W. Leonard: CONTROL OF ELECTRICAL DRIVES. Springer-Verlag, Berlin, 2001
I. Boldea, S. A. Nasar : ELECTRIC DRIVES, CRC Press, New York, 1999.
P. Vas: VECTOR CONTROL of AC MACHINES, Oxford University Press, New York, 1990.
T.J.E. Miller: SWITCHED RELUCTANCE MOTORS AND THEIR CONTROL. Clarendon Press, Oxford, 1993.
W. Leonard: CONTROL OF ELECTRICAL DRIVES. Springer-Verlag, Berlin, 2001
Teaching methods
The theoretical part of the course is integrated by numerical simulations of electrical drives in SIMULINK of MATLAB. Assignments of project works to groups of 3-5 students.
Assessment methods
Discussion of theoretical topics and presentation of the project work
Teaching tools
Copy of the transparencies employed for lecturing.
Basic mathematical models of electrical drives for numerical simulations
Office hours
See the website of Domenico Casadei
See the website of Yasser Gritli
SDGs
This teaching activity contributes to the achievement of the Sustainable Development Goals of the UN 2030 Agenda.